NO328347B1 - Procedure for cleaning oily cuttings coming from drilling oil wells and at the same time recycling the oil component - Google Patents

Description

The present invention relates to a method for cleaning oil-containing cuttings that comes from the drilling of oil wells, and at the same time recovery of the oil component.

Of documents that may be of interest in this context, mention should be made of CA 2436625, US 6347675, EP 238527, US 4434028 and WO89/02774.

The term "drilling cuttings", as used in the present description and claims, indicates the crushed material formed during drilling and mixed with drilling mud. This is therefore a fluid with a rheology typical of aqueous suspensions with a high content of solids, such as sludge or slurry.

The function of drilling mud is to consolidate the walls of the hole of an oil well, protect the metal parts from corrosion and cool and lubricate the drill bit during drilling. The mud, which can be water-based or oil-based, also adds pressure to hold the geological formation together and has the function of guiding the cuttings formed by the excavation carried out by the drill bit to the surface.

Oil-based sludge includes e.g. mineral oil, barite, bentonite and other additives such as emulsifiers and polymers

In the past, drilling cuttings, mostly from offshore platforms, were discharged into the sea and created an unacceptable level of environmental impact. There are also significant problems with regard to dispersion on the bottom.

Various methods are used to remove oil-based sludge from the cake, among these, washing systems with detergents, thermal and distillation systems. The main disadvantage of these methods is respectively linked to low efficiency, limited safety, especially when operating at sea, high costs and complicated plant construction.

The use of a compressible solvent for the recovery of oil from sawdust, with acceptable concentration levels of residual product in the solid, was proposed with reference to "supercritical processes", in other words to bring the fluid above its critical conditions during the processing of the sawdust The application, described in S .Saintpére et al

(2000), "Supercritical C02 extraction applied to oily drilling cuttings", SPE 63126, SPE

International, which uses carbon dioxide (C02), is not competitive from an economic point of view

It was also confirmed that the treatment process carried out with C02 under supercritical conditions is highly dependent on the physico-chemical properties of the cake which jeopardizes the removal efficiency, in terms of oil recovery and residue concentration in the solids.

The applicant has now found that the oil part of the cuttings coming from the drilling of oil wells can be removed by an extraction method which uses a fluid which is compressible to liquid form as a solvent, to obtain an oil with the same properties as the mud product and which, when suitable additives have been added, can be reused in other boreholes whereby the solid parts (cuttings) can be returned to the environment or sent for normal disposal.

With regard to the compressible fluid brought to so-called "supercritical" conditions, or past the critical point, the use of the compressible solvent in liquid form has the following advantages: - degree of recovery of the oil comparable to that obtained for fluid in the supercritical condition, except for C02, which however operates at lower pressure and

temperatures,

- less dehydration of the solid phase and therefore less production of water that must be sent for treatment, - reduction of construction costs, due to the limited operating pressures, in terms of equipment and pipes.

By using the functional scheme indicated below as a thermocompression process, energy consumption is greatly reduced, thereby allowing the reduction of treatment costs to competitive levels with consolidated technologies.

In addition, the oil fraction removed by the use of the compressible fluid is completely recovered at the end of the process without being contaminated by processing solvents, and can be reused for subsequent processing, after refining processes and/or the addition of suitable additives. Finally, the initial treatment of the fixed charge, effected through a mixture with inert material, to overcome the process restrictions that limit its applicability. The use as a solvent of a fluid compatible with problems associated with pollution is in accordance with the increasing demand for the protection of the environment, as a result of the harmless nature of the fluid and also because of the complete lack of polluting waste products coming from the process

The limitations in the use of said solvents can be overcome by exploiting the physico-chemical properties of the solvent so that it passes from a thermodynamic cycle to a thermocompression cycle, characterized by moderate operating pressures and low energy requirements

According to this, the present invention relates to a method for cleaning oil-containing cuttings that comes from the drilling of oil wells, and at the same time recovery of the oil component, characterized by the following steps-

a) optional mixing of the sawdust with an inert material,

b) mixing said cake with carbon dioxide as solvent, compressible to

liquid form at a pressure value varying from 45 to 80 bar and a temperature which

corresponds to the degree of saturation, with dissolution of the oil fraction on the cake,

c) removal of the liquid phase (solution) from the solid phase (cake),

d) expansion and heating of the materials leaving step (c), with recovery of

the flowing oil fraction and the solvent in vapor phase,

e) cooling and condensing the solvent and its recycling to step a), after any subcooling,

as the mixing of the cake takes place at a pressure of 45 to 80 bar, whereby the separation of the oil fraction is carried out at a pressure of 30 to 65 bar, and as the degree of subcooling for the liquid phase varies from 0 to 5°C

Embodiments of the present invention are indicated in the independent patent claims

The method according to the present invention has significant advantages both from an economic and an environmental point of view. The drill cuttings, defined by current regulations as harmful waste products, have such properties that, after treatment, they are compatible with the environment, whereby the removed oil part can be reused as drilling mud, possibly with the addition of additives.

The solvent used is inert during the process and in the surrounding conditions. The process works with a closed cycle, with complete recovery of the solvent.

In the thermocompression cycle, a compressor is used to compress the solvent in vapor-gas form, and the phase transitions of the process fluid occur by mutual energy exchange in the form of the heat of evaporation and condensation being mutually exchanged

The method according to the present invention includes the use of machines with small dimensions and thus with the possibility of application also at sea. From an economic point of view, the present method is believed to be of great interest when it comes to alternative processes on land.

Some application examples are given in the following for illustration only, with reference to the removal of the oil fraction from cake after two processes, the thermocompression cycle and the "classic" cycle.

Example 1: thermocompression cycle

A typical embodiment of the method according to the present invention is schematized in the block diagram illustrated in Figure 1, with reference to the thermocompression process.

The sawdust to be treated is well mixed with a certain amount of inert material, in a percentage varying from 10 to 40% by weight, usually 20% by weight.

The resulting mass is then supplied to a pressure vessel, said extraction column 3 is according to known technology. The extraction column is equipped with screen walls upstream and downstream, generally formed of porous steel, to retain the cuttings.

After closing, the extraction column 3 is pressurized with the solvent in vapor phase, taken from the collection tank 1. The pressurization can be carried out from the inlet located at the bottom of the container 1 or from the inlet located at the top, usually from the bottom.

When a pressure value is reached which is close to that in the collection tank 1, the steam feed is interrupted and the extraction column 3 is supplied with the solvent in the liquid phase, still from the collection tank 1. The pressurization can be carried out from the inlet located at the bottom of the container or from the inlet located at the top, usually from the bottom.

The complete filling of the reactor is achieved by using a volumetric compressor 7 placed downstream of the extraction column 3, by sucking the steam from the extraction column and driving the liquid from the collection tank 1

The liquid is evenly distributed in the sawdust, and dissolves the oil fraction

The entire system is pressurized according to an analogous procedure, in all parts. The removal phase begins by continuously supplying the liquid to the extraction column 3, using a pump system, not illustrated, with the extraction column aligned with respect to the flow of the solvent

The liquid solution leaving the extraction column 3, comprising the solvent and the dissolved oil fraction, flows through a valve 4 and undergoes decompression to a lower pressure value. The oil fraction is thus continuously removed from the cake.

The liquid-vapor mixture that is formed after decompression is sent to a heat exchanger 5 whose function is to bring the solvent that forms the mixture into the vapor phase, while the oil fraction is separated from the flow as a liquid phase

The mixture of vapor solvent and liquid oil phase is passed through a separator 6 with a cyclone effect, or a series of several separators with gravity and cyclone effect, to achieve the complete separation of the liquid oil fraction from the solvent vapor stream.

An optional, additional separation filter can be included in the separation section

The liquid oil fraction is collected at the bottom of the separator or separators 6, from where it is removed by intermittent discharge through a valve placed at the bottom of each separator 6.

The vapor-gas phase solvent leaving the separation section is cooled and condensed in a condenser 8, and recovered in the collection tank 1, from where it is sent, after subcooling 2, for reuse in the extraction cycle

With reference to the thermocompression cycle, the movement of the solvent takes place by means of a volumetric compressor 7 which sucks the vapor leaving the separation section and compresses it to the pressure value in the collection tank 1.

The removal phase continues until the desired recovery rate is reached, as the percentage of oil fraction removed in relation to its original content in the wood chips (removal fraction), or the proportion of the oil fraction removed in relation to the amount of treated raw wood chips (yield fraction).

The time parameter for the removal process is given by the ratio between the amount of solvent used and the weight of the cake treated. This weight ratio depends on the process parameters, the type of solvent used and the type of cake treated, and varies from 2 to 30, usually 8.

When the removal phase has been interrupted by stopping the continuous flow of solvent, the extraction column 3 is isolated and the solvent contained therein is recovered using the process compressor or an auxiliary compressor. The solvent is recovered in collection tank 1.

The rewarming phase for the solvent is followed by the final depressurization phase to the atmospheric value and then the recovery of the treated cake, according to known procedures.

Data with reference to a test conducted as per the procedure described above is as follows-

Example 2: Classical cycle

A typical embodiment of the method according to the present invention, according to the classical process, is schematized in the block diagram illustrated in figure 2

The sawdust to be treated is well mixed with a certain amount of inert material, in a percentage varying from 10 to 40% by weight, generally 20% by weight

The resulting mass is then fed to the extraction column 3, according to known techniques

The extraction column is analogous to that used in the thermocompression cycle.

After closing, the extraction column 3 is pressurized with the solvent in vapor phase, taken from the collection tank 1, as in the previous example

When a pressure value is reached that is close to the collection tank value, the steam supply is interrupted, and the extraction column 3 is supplied with the solvent in the liquid phase, still from the collection tank 1. Also in this case, the complete filling of the extraction column 3 is achieved by using a volumetric pump placed upstream of the extraction column, by suck the liquid from the collection tank 1.

The liquid is evenly distributed on the sawdust, and dissolves the oil fraction.

The entire plant is pressurized following an analogous procedure, in all parts. The removal phase begins by continuously supplying the liquid to the extraction column 3 using a pump system, not illustrated, with the extraction column placed in line with regard to the flow of the solvent.

The liquid solution leaving the extraction column 3, comprising the solvent and the dissolved oil fraction, flows through the valve 4 and undergoes decompression to a lower pressure value. The oil fraction is thus continuously removed from the cake.

The liquid-vapor mixture formed after decompression is sent to a heat exchanger 5 which has the function of bringing the solution that forms the mixture to the vapor phase, whereby the oil fraction is separated from the flow as liquid phase

The mixture of vapor solution and liquid oil phase is passed through a separator 6 with a cyclone effect, or a string of several separators with gravity and cyclone effect, to achieve the complete separation of the liquid oil fraction from the solvent vapor stream.

An additional separation filter can be included in the separation section

The liquid oil fraction is collected at the bottom of the separator or separators 6, from which it is removed by intermittent discharge through a valve placed at the bottom of the separator or each separator.

The solvent in vapor-gas phase leaving the separation section is cooled and condensed in a condenser 8, and recovered in the collection tank 1, from where it is sent after subcooling in a cooler 2, for use again in the extraction cycle

With reference to the "classic" removal cycle, the movement of the solvent takes place by means of a volumetric pump which sucks the liquid leaving the collection tank 1 and compresses it to the pressure value in the collection tank.

The removal phase continues until the desired recovery rate is reached, expressed as the percentage of the oil fraction removed in relation to its original content in the wood chips (removal rate), or the proportion of the oil fraction removed in relation to the amount of treated raw wood chips (yield rate)

The time parameter in the removal process is given by the ratio between the amount of solvent used and the weight of the treated sawdust. This weight ratio depends on the process parameters, the type of solvent used and the type of cake treated, and varies from 4 to 30, usually 10.

When the removal phase has been interrupted by stopping the continuous flow of solvent, the extraction column 3 is isolated and the solvent contained therein is recovered by the use of the auxiliary compressor, which is necessary in this case for compressing the vapor to the pressure in the collection tank 1

The recovery phase of the solvent is followed by the final depressurization phase to the atmospheric value and then the recovery of the treated cake, according to known procedures

Data referring to a test performed according to the procedure described above are as follows

Claims (12)

1 Procedure for cleaning oily cuttings from the drilling of oil wells, and simultaneous recovery of the oil component, characterized by the following steps- a) optional mixing of the cuttings with an inert material, b) mixing of said cuttings with carbon dioxide as solvent, compressible to liquid form at a pressure value varying from 45 to 80 bar and a temperature corresponding to the degree of saturation, with dissolution of the oil fraction in the cake, c) removal of the liquid phase (solution) from the solid phase (cake), d) expansion and heating of the materials which leaves step (c), with recovery of the flowing oil fraction and the solvent in vapor phase, e) cooling and condensation of the solvent and its recycling to step a), after possible subcooling, as the mixing of the cake takes place at a pressure of 45 to 80 bar, whereby the separation of the oil fraction is carried out at a pressure of 30 to 65 bar, and as the degree of subcooling for the liquid phase varies from 0 to 5°C 2 Method according to claim 1, in which the mixing step for the cake and the separation step for the oil fraction takes place at a temperature close to the saturation value of the liquid phase. 3 Method according to claim 1 or 2, in which the solvent is fed to an extraction vessel (3) in a ratio of 2 to 20 times the weight of the cake 4 Process according to one of the claims 1 to 3, in which the sawdust is mixed with an inert material that makes up 10 - 40% of the total weight 5 Method according to one of claims 1 to 4, in which the inert material comprises cake which has already been treated and therefore partially recycled 6. Method according to one of claims 1 to 5, in which the movement of the solvent takes place using a volumetric compressor (7) placed between the separation section and the collection tank (1) 7 Method according to one of claims 1 to 5, in which the movement of the process fluid takes place using a volumetric pump placed between the collection tank (1) and the extraction column (3). 8 Method according to one of claims 1 to 7, in which the recovered oil phase is separated using a separator (6) or several separators in series. 9. Method according to claim 8, in which the separation section comprises a single separator (6) with cyclone effect. 10 Method according to claim 8, in which the separation section comprises two separators (6), the first with a gravity effect, the second with a cyclone effect 11 Method according to claims 8-10, in which a filter for separating the entrained liquid is placed downstream of the separation section. 12 Method according to claim 6, in which the phase transitions for the solvent occur by energy exchange between the heat of vaporization and the heat of condensation.